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CHEMICAL ENGINEERING Ph.D. PROGRAM INFORMATION Educational Objectives: The educational objectives of this program are to educate graduates to have careers in research and development departments of national and international companies requiring expertise in special fields and in academic institutes and can make constant progress in their profession.
Goals:
The goals of the Chemical Engineering Department of Yeditepe University is to educate students to become chemical engineers with a doctorate degree who help develop novel Chemical Engineering Technologies, use advanced Chemical Engineering knowledge in behalf of human necessities, make the research information to be used for the society from ethical and social point of view.
PROGRAM LEARNING OUTCOMES
- Understand and apply fundamental sciences, mathematics and engineering sciences at high level.
- Have a wide and deep knowledge in his/her field including the latest progresses.
- Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research.
- Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
- Understand a genuine research process independently, design, apply and carry through; manage this process.
- Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
- Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
- Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written.
- Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
- Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
Teaching Methods
Teaching-learning methods and strategies are selected in the way to enhance the abilities of the students in working individually, recognition of the need for lifelong learning, observing, teaching others, presentation, critical thinking, working in a team, employing information technologies effectively.
Moreover, it is respected that the teaching methods support the students with different types of talents. The teaching methods used in the program are listed below*:
(*) According To the properties of the lecture, one or more methods specified below may be applied.
Teaching Methods* Essential Learning Facilities Tools used
Lecture Listening and understanding Standard class technologies, multimedia tools, projector, computer, overhead projector
Lecture with discussion
Listening and understanding, observation/circumstances processing, critical thinking, problem formulation
Standard class technologies, multimedia tools, projector, computer, overhead projector
Problem Solving Special skills planned in advance
Case study Special skills planned in advance
Brain Storming Listening and understanding, observation/circumstances processing, critical thinking, problem formulation, group study
Standard class technologies, multimedia tools, projector, computer, overhead projector
Discussion in a small group
Listening and understanding, observation/circumstances processing, critical thinking, problem formulation
Standard class technologies, multimedia tools, projector, computer, overhead projector
Seminar Research – Life-long learning, writing, listening, informatics, listening and understanding, administrative skills
Standard class technologies, multimedia tools, projector, computer, overhead projector, special facilities
Group Study Research – Life-long learning, writing, listening, informatics, listening and understanding, administrative skills, group study
Internet databases, library databases, e-mail, online discussion, web-based discussion forums
Laboratory observation/circumstances processing, informatics administrative skills, group study Special facilities
Homework Research – Life-long learning, writing, listening, informatics Internet databases, library databases, e-mail
Investigation / Sample Survey Study
Research – Life-long learning, writing, reading
Panel Listening and understanding, observation/circumstances processing
Standard class technologies, multimedia tools, projector, computer, overhead projector, special facilities
Guest Speaker Listening and understanding, observation/circumstances processing
Standard class technologies, multimedia tools, projector, computer, overhead projector, special facilities
Student Ensembles Facilities / Projects
observation/circumstances processing critical thinking, problem formulation, group study, research-long-life learning, reading, writing, administrative skills, special skills plnned beforehand.
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
MODELING AND ANALYSIS OF CHEMICAL ENGINEERING SYSTEMS
CHBE 512
1-2 2 + 2 3 10
Prerequisites NONE
Language of Instruction English
Course Level Ph. D. Degree (Third Cycle Programmes)
Course Type Compulsory
Course Coordinator
Instructors Assist. Prof. Betül Ünlüsü
Assistants
Goals The aim of this course is to provide students with the ability to model chemical engineering systems and solve model equations using analytical and numerical techniques.
Content
Modeling and mathematical formulation of lumped-parameter and distributed-parameter systems encountered in chemical engineering. Analytical and numerical methods used in the solution of ordinary and partial differential equations.
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Gains the ability to derive models for chemical engineering systems in a hierarchy of levels from the simplest to the most complex using the fundamental laws of physics
1
1,2 A,C
2) Acquires the ability to solve ordinary and partial differential model equations using analytical and numerical techniques
1 1,2 A,C
3) Gains the ability to communicate effectively in English
8 1,2 A,C
Teaching Methods: 1: Lecture, 2: Question-Answer, 3: Lab, 4: Case-study
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Project
COURSE CONTENT
Week Topics Study Materials
1
MODELING OF CHEMICAL ENGINEERING SYSTEMS (MASS, MOMENTUM AND ENERGY CONSERVATION EQUATIONS)
Textbook
2
MODELING OF CHEMICAL ENGINEERING SYSTEMS (MASS, MOMENTUM AND ENERGY CONSERVATION EQUATIONS)
Textbook
3
ANALYTICAL SOLUTION METHODS FOR ORDINARY DIFFERENTIAL EQUATIONS (FIRST ORDER LINEAR AND NONLINEAR EQUATIONS)
Textbook
4
ANALYTICAL SOLUTION METHODS FOR ORDINARY DIFFERENTIAL EQUATIONS (SECOND ORDER LINEAR AND NONLINEAR EQUATIONS)
Textbook
5 ANALYTICAL SOLUTION METHODS FOR ORDINARY DIFFERENTIAL EQUATIONS (METHOD OF FROBENIUS) Textbook
6 ANALYTICAL SOLUTION METHODS FOR ORDINARY DIFFERENTIAL EQUATIONS (BESSEL’S EQUATION) Textbook
7 MIDTERM EXAM I
Textbook
8
ANALYTICAL SOLUTION METHODS FOR PARTIAL DIFFERENTIAL EQUATIONS (METHOD OF COMBINATION OF VARIABLES)
Textbook
9
ANALYTICAL SOLUTION METHODS FOR PARTIAL DIFFERENTIAL EQUATIONS (METHOD OF SEPARATION OF VARIABLES)
Textbook
10
ANALYTICAL SOLUTION METHODS FOR PARTIAL DIFFERENTIAL EQUATIONS (METHOD OF LAPLACE TRANSFORMATION)
Textbook
11
ANALYTICAL SOLUTION METHODS FOR PARTIAL DIFFERENTIAL EQUATIONS (METHOD OF LAPLACE TRANSFORMATION)
Textbook
12 NUMERICAL SOLUTIONS OF DIFFERENTIAL EQUATIONS
Textbook
13 NUMERICAL SOLUTIONS OF DIFFERENTIAL EQUATIONS
Textbook
14 MIDTERM EXAM II
Textbook
RECOMMENDED SOURCES
Textbook RICE, R. G., DO, D. D., APPLIED MATHEMATICS AND MODELING FOR CHEMICAL ENGINEERS, 2nd ED., WILEY, 2012
Additional Resources
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 2 63
Assignment 6 37
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 60
Total 100
COURSE CATEGORY Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level. +
2 Have a wide and deep knowledge in his/her field including the latest progresses.
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research.
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. +
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Including the exam week: 16x Total course hours) 14 3 42
Hours for off-the-classroom study (Pre-study, practice) 14 10 140
Mid-terms 2 4 8
Ödev 6 8 48
Final examination 1 5 5
Total Work Load 243
Total Work Load / 25 (h) 9.72
ECTS Credit of the Course 10
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
ADVANCED ENGINEERING THERMODYNAMICS ChBE 514 1 or 2 3 + 0 3 10
Prerequisites -
Language of Instruction English
Course Level PhD
Course Type Compulsory
Course Coordinator -
Instructors Assist. Prof. Levent Organ
Assistants -
Goals
The aim of this course in general is to present thermodynamics and its applications in the context of available energy (exergy). Following a detailed classification of thermodynamics, fundamental concepts and derivations of thermodynamics are presented and discussed along the lines of relevant energy and available energy (exergy) applications.
Content
The course comprises the subtitles of classification, basic concepts, definitions and interpretations of thermodynamics; introduction to available energy analysis: goal and definitions; 1. Law of thermodynamics and energy; energy analysis in a control volume; 2.Law of thermodynamics and entropy; entropy generation rate in a control volume; thermodynamic analysis of steady state flow systems; fundamentals of available energy; available energy expression and entropy analysis; available energy analysis in flow systems; available energy (2.Law) efficiency or effectiveness; chemical availability; total (thermomechanical and chemical) available energy and thermoeconomy.
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Acquires the knowledge in mathematics, science and engineering subjects in the context of energy and available energy under thermodynamics at Master’s level; ability to use theoretical and applied information in these areas to solve engineering problems.
1,2,3 1 A,C
2) Gains the ability to identify, formulate, and solve complicated engineering problems related to energy and available energy at Master’s level; ability to select and apply proper analysis methods for this purpose.
1,2,3
1 A,C
3) Gains the ability to communicate effectively in writing and orally in the English language
8 1 A,C
Teaching Methods:
1: Lecture, 2: Question-Answer, 3: Discussion, 9: Simulation, 12: Case Study
Assessment Methods: A: Testing, B: Experiment C: Homework and/or Project
COURSE CONTENT
Week Topics Study Materials
1 Thermodynamics: classification, basic concepts, definitions and interpretations
Resources listed, course notes
2 Introduction to available energy analysis: goal and definitions “
3 1. Law of thermodynamics and energy “
4 Energy analysis in a control volume “
5 2.Law of thermodynamics and entropy “
6 Entropy generation rate in a control volume “
7 Thermodynamic analysis of steady state flow systems “
8 Midterm exam “
9 Fundamentals of available energy; available energy expression and entropy analysis “
10 Available energy analysis in flow systems; efficiency or effectiveness “
11 Chemical availability “
12 Total (thermomechanical and chemical) available energy “
13 Thermoeconomy “
14 Project presentation “
RECOMMENDED SOURCES
Textbook Moran, M.J., Shapiro, H.N.,”Fundamentals of Engineering Thermodynamics”, 4 ed. John Wiley&Sons, Inc., New York, 2000. [MS]
Course Notes Course notes prepared from various references, mainly Moran, are distributed to the students (unpubl).
Additional Resources
1.Smith,J.M., Van Ness,H.C., Abbott,M.M.,”Introduction to Chemical Engineering Thermodynamics”, 7.ed., McGraw-Hill, 2005. [SVN7] 2.Prausnitz,J.M., Lichtenthaler,R.N.,”Molecular Thermodynamics of Fluid-Phase-Equilibria”, 3.ed., Prentice Hall, 1999; 1.ed. 1969; 2.ed.1986. [P3] 3.a) Reid,R.C., Prausnitz,J.M., Sherwood,T.K., 3.ed., 1977; b) Reid, R.C., Prausnitz,J.M., Poling,B.E.,4.ed.,1987; c) Poling,B.E., Prausnitz,J.M., O’Connell,J.P., 5.ed.,2001, “The Properties of Gases and Liquids”, McGraw-Hill. [PROP] 4.Dinçer, S., “Denge Süreçlerinin Termodinamiği”, Boğaziçi Üniversitesi Yayınları, 1984. [D]
MATERIAL SHARING
Documents -
Assignments -
Exams -
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-term 1 41.65
Project 1 41.65
Homework 8 (bonus: add 5% of HW’s to the overall grade)
Attendance 16.7
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE
60 (add 5% bonus points for HW’s to the overall grade)
Total 100 (add 5% bonus points for
HW’s to the overall grade)
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5 1 Understand and apply fundamental sciences, mathematics and engineering
sciences at high level. X
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Including the exam week: 14x Total course hours) 14 3 42
Hours for off-the-classroom study (Pre-study, practice) 14 8 112
Mid-term 1 3 3
Project 1 40 40
HW 8 6 48
Final examination 1 4 4
Total Work Load 249
Total Work Load / 25 (h) 10
ECTS Credit of the Course 10
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
TRANSPORT PHENOMENA ChBE 534 1 or 2 3 + 0 3 10
Prerequisites -
Language of Instruction English
Course Level PhD
Course Type Compulsory
Course Coordinator -
Instructors Prof.Dr. Salih Dinçer
Assistants -
Goals
The aim of this course is to teach the formulation and application of momentum, energy and mass transport concepts using shell balances and derived transport equations in vector-tensor notation, together with the approaches used for the relevant analytical solutions.
Content
The course comprises an introduction to vector-tensor notation and relevant vector-tensor operations useful in transport phenomena, and the presentation of the concepts, formulations, analogies, analytical approaches and applications used for each of momentum, energy and mass transport.
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Acquires the knowledge of mathematics, science and engineering subjects pertaining to momentum, energy and mass transfer at Master’s level; ability to
1,2,3 1 A,C
use theoretical and applied information in these areas to solve relevant engineering problems.
2) Gains the ability to identify, formulate, and solve complicated science and engineering problems related to momentum, energy and mass transfer at Master’s level; ability to select and apply proper analysis methods for this purpose.
1,2,3 1 A,C
3) Gains the ability to communicate effectively in writing and orally in the English language
8 1 A,C
Teaching Methods:
1: Lecture, 2: Question-Answer, 3: Discussion, 9: Simulation, 12: Case Study
Assessment Methods: A: Testing, B: Experiment C: Homework
COURSE CONTENT
Week Topics Study Materials
1 Introduction to vector-tensor notations and relevant vector-tensor operations useful in transport phenomena
Textbook, library, Sci Direct
2 The mechanism of momentum transport and viscosity; shell momentum balances and velocity distributions in laminar flow “
3 The equations of change (conservation) for isothermal systems “
4 Velocity distributions with more than one independent variable; velocity distributions in turbulent flow “
5 Interphase momentum transport in isothermal systems “
6 Macroscopic balances for isothermal flow systems “
7 The mechanism of energy transport and thermal conductivity; shell energy balances and temperature distributions in solids and laminar flow
“
8 Midterm exam 1 “
9 The equations of change (conservation) for nonisothermal systems; introduction to temperature distributions with more than one independent variable
“
10 Interphase energy transport in nonisothermal systems; macroscopic balances for nonisothermal systems “
11 The mechanisms of mass transport and the diffusivity; concentration distributions in solids and laminar flow “
12 Equations of change (conservation) for multicomponent systems; interphase mass transport in nonisothermal systems “
13 Interphase mass transport in nonisothermal systems (contd); macroscopic balances for multicomponent systems “
14 Midterm exam 2 “
RECOMMENDED SOURCES
Textbook Bird, R.B., Stewart,W.E., Lightfoot, “Transport Phenomena”, John Wiley & Sons, Inc., New York, revised 2.ed., 2007. [BSL]
Additional Resources Library and Sci Direct
MATERIAL SHARING
Documents -
Assignments -
Exams -
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-term 2 83.3
Homework 12 (Bonus: 5% of HW’s added to the total points)
Attendance 16.7
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE
60 (5% of HW’s added as bonus to the total points)
Total 100 (5% of HW’s added as bonus to the total points)
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5 1
Understand and apply fundamental sciences, mathematics and engineering sciences at high level. X
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Including the exam week: 14x Total course hours) 14 3 42
Hours for off-the-classroom study (Pre-study, practice) 14 10 140
Mid-terms 2 3 6
HW’s 12 5 60
Final examination 1 4 4
Total Work Load 252
Total Work Load / 25 (h) 10
ECTS Credit of the Course 10
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
ADVANCED CHEMICAL AND BIOLOGICAL REACTION ENGINEERING
CHBE 562 1 3 + 0 3 8
Prerequisites -
Language of Instruction English
Course Level MS Degree (Second Cycle Programmes)
Course Type Compulsory
Course Coordinator Prof. Dr. Mustafa Özilgen
Instructors
Assistants
Goals Enabling graduate engineering students carry out modeling studies by employing advanced chemical engineering kinetics knowledge to biological and chemical data
Content
Mathematical modeling (transport phenomena, analogy and empirical models, 80 % -20 % rule), review of priciples of mathematical modeling as applied to kinetics of biological and chemical systems and reactor design. Biological reactor design , product formation, growth and sterilization models. Affect of axially dispersed plug flow analysis in biological and chemical reactor efficiency
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Learns mathematical modeling 1,2, 3, 9, 12 A,C
2) Learns why the chemicals react: theoretical aspects, data analysis, reliability of data
1,2, 3, 9, 12 A,C
3) Gains knowledge on microbial kinetics: Metabolic engineering, growth product formation, sterilization models
1,2, 3, 9, 12 A,C
4) Gains the ability to design ideal reactors 1,2, 3, 9, 12 A,C
5) Analyzes real reactors in terms of series and parallel reactor systems with chemical and biological applications
1,2, 3, 9, 12 A,C
6) Designs non ideal reactors with emphasis on axially dispersed flow
1,2, 3, 9, 12 A,C
Teaching Methods:
1: Lecture, 2: Question-Answer, 3: Discussion, 9: Simulation, 12: Case Study + simulation of the literature data from refereed articles
Assessment Methods: A: Testing, C: Homework
COURSE CONTENT
Week Topics Study Materials
1-2 Mathematical modeling Textbook + Articles + library + computer program packages
3-6 Why do the chemicals react: theoretical aspects, data analysis, reliability of data
Textbook + Articles + library + computer program packages
7-8 Microbial kinetics: Growth product formation, sterilization models
Textbook + Articles + library + computer program packages
9-10 Overview of ideal reactor design Textbook + Articles + library + computer program packages
11-12 Real reactor analysis in terms of series and parallel reactor systems with chemical and biological applications
Textbook + Articles + library + computer program packages
11-12 Real reactor analysis in terms of series and parallel reactor systems with chemical and biological applications
Textbook + Articles + library + computer program packages
13 Discussion and presentation of the student projects Textbook + Articles + library + computer program packages
14 Non-ideal reactor design with emphasis on axially dispersed flow
Textbook + Articles + library + computer program packages
15-16 General Revision and discussion, case studies, crititisim of Textbook + Articles +
literature library + computer program packages
RECOMMENDED SOURCES
Textbook Özilgen M. Handbook of food process modeling and statistical quality control, 2nd ed. Taylor & Francis, USA, 2011
Additional Resources Instructors refereed publications and presentations in international symposia
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 2 10 x 2
Homeworks 2 5 x2
Term project 1 70
Total 100
CONTRIBUTION OF FINAL EXAMINATION (turned in as a project) TO OVERALL GRADE 70
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 20
Total 100
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5 1
Understand and apply fundamental sciences, mathematics and engineering sciences at high level.
X
2 Have a wide and deep knowledge in his/her field including the latest progresses.
X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research.
X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
X
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
X
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
x
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
x
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written.
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
x
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
x
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Including the exam week: 16x Total course hours) 16 3 48
Hours for off-the-classroom study (Project) 16 8 128
Mid-terms 2 10 20
Final examination 1 10 10
Total Work Load 206
Total Work Load / 25 (h) 8.24
ECTS Credit of the Course 8
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Advanced Instrumental Analysis CHBE 525 1 3+1 3 7
Prerequisites ---
Language of Instruction English
Course Level Graduate (Second/Third Cycle Programme)
Course Type Elective
Course Coordinator
Instructors Assist. Prof. Semin Funda Oğuz
Assistants
Goals
Understanding the principles and components of analytical instruments and their applications in science, Experiencing how to prepare samples for analysis and how to design experiment, Developing capability to resolve analytical problems in science.
Content
This course is advanced instrumental analysis course which emphasizes principles and applications of selected analytical instruments in different fields. The focus will be more on characterization and separation techniques. Lecture topics cover mainly molecular spectroscopy (UV-VIS, IR, NMR, and mass spectrometry), separation methods (GC, LC, and HPLC), atomic spectroscopy (AAS, AES, and ICP-MS), electroanalytical methods (potentiometry, voltammetry, impedance spectrometry) and thermal analysis methods (DSC, TGA, DMA). In the laboratory, students gain hands-on experience by performing special experiments, the results of which will be discussed in the class.
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Ability to understand the working principles of modern instrumentations
1
1,2,3 A,B,C
2) Ability to define application areas of instrumentation techniques
1,2 1,3 A, B, C
3) Ability to apply the instrumentation techniques for specific problems
5 3,4 B, C, D
4) Ability to interpret the instrumental analyses results
1, 5, 8 1, 3, 4 A,B,C
5) Ability to follow the improvements in instrumentation techniques
3, 8 1, 4 C, D
Teaching Methods: 1: Lecture, 2: Question-Answer, 3: Lab, 4: Case-study
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Project
COURSE CONTENT
Week Topics Study Materials
1 Introduction to Molecular Spectroscopy Textbook
2 UV/VIS Spectroscopy Textbook
3 IR Spectroscopy Textbook
4 Mass Spectrometry/ UV/VIS Experiment Textbook/Web sources
5 NMR Spectroscopy/ IR Spectroscopy Experiment Textbook/Web
sources
6 NMR Spectroscopy/ Mass Spectrometry Experiment Textbook/Web
sources
7 Separation Techniques and Liquid Chromatography Textbook
8 Liquid Chromatography Textbook
9 Gas Chromatography Textbook
10 HPLC and GC Experiments Web sources
11 Atomic Spectroscopy/ Atomic Spectroscopy Experiment Textbook
12 Electroanalytical Methods/ Electroanalytical Experiment Textbook
13 Thermal Analysis Methods/ Thermal Analysis Experiment Web sources
14 Presentations Textbook/Web
sources
RECOMMENDED SOURCES
Textbook Skoog, Holler and Niemann, ”Principles of Instrumental Analysis”, 5th Edition, Brooks/Cole
Additional Resources Rouessac F. and Rouessac A., “Chemical Analysis, Modern Instrumentation Methods and Techniques”, 2nd Edition, Wiley
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-term 1 40
Assignment 2 20
Lab Report 1 20
Term Project Presentation 1 20
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 30
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 70
Total 100
COURSE CATEGORY Field Course
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Acquire expanded and in-depth information via performing scientific research in the field of Chemical Engineering, evaluate, interpret and implement knowledge.
X
2 Be knowledgable in the contemporary techniques and methods applied in Chemical Engineering and their respective constraints.
X
3 Be cognizant of the novel and developing applications of his/her profession, study and learn them as required.
X
4 Formulate Chemical Engineering problems, develop methods to solve them and implement innovative techniques in solutions
5 Design and conduct analytical modeling and experimental research, analyze and interpret complex problems encountered in this process.
X
6 Develop novel and/or original ideas and methods; conceive innovative solutions in systems, component and process design
7 Complete information via processing limited or incomplete data by the use of scientific methods and implement it; integrate knowledge from different disciplines
8 Communicate in at least one foreign language at the level of European Language Portfolio B2 orally and in writing.
X
9 Communicate stages and results of his/her studies in a systematic and clear manner orally or in writing in intra or interdisciplinary national and international settings.
10 Defines societal and environmental aspects of Chemical Engineering applications
11 Observe social, scientific and ethical values during collection, interpretation, and dissemination of data and in all professional activities.
12 Lead multidisciplinary teams, develop solution methodologies for complex problems and take responsibility
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam weeks: 14x Total course hours) 14 3 42
Hours for off-the-classroom study (Pre-study, practice) 14 6 84
Midterm examination 1 2 2
Homework 2 10 20
Laboratory Reports 1 15 15
Project 1 15 15
Final examination 1 3 3
Total Work Load 181
Total Work Load / 25 (h)
ECTS Credit of the Course 7
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Fundamentals of Colloid and Surface Chemistry
CHBE 565
3+1 3 7
Prerequisites
Language of Instruction English
Course Level PhD
Course Type Elective
Course Coordinator Assoc. Prof. Seyda Malta
Instructors Assoc. Prof. Seyda Malta
Assistants
Goals
The aim of this course is to give the fundementals of colloid and surface chemistry and give the students the ability to apply this knowledge to nanotechnology. The course is supplemented with experiments to solidify the theoretical knowledge.
Content
Fundamentals of colloid and surface chemistry with theoretical and laboratory work. Topics include: self assembly of amphiphiles, Brownian motion, surface chemistry and monolayers, surface tension and contact angle, electrostatic interactions in colloidal systems, structure and properties of micelles in industrial and biological processes, bilayer systems, membranes in biological systems and transport, micro-and macro emulsions. Lab work includes: surface tension and conductimetric determination of CMC, preparation and characterization of different colloidal structures using UV-Vis Spectrophotometer and microscopy techniques, preparation of microemulsions, and reactions in microemulsion droplets.
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Acquires adequate knowledge in science and technology in colloid and surface chemistry; ability to use theoretical and applied information in these areas to solve relevant problems.
1 1 A
2) Gains the ability to devise, select, and use modern techniques such as conductivity meter, spectrophotmeter, tensiometer, zeta-potential, viscosity meter, etc needed for engineering practice; ability to employ Excel to plot data and make calculations and Word to write reports effectively.
4 1, 3 A, B
3) Gains the ability to conduct experiments, gather data for investigating problems on colloid and surface chemistry such as sedimetation, adsorption, self-assembly and analyze and interpret results from these experiments and also data from other techniques such XRD, microscopy and light scattering.
3 1, 3 B
4) Gains the ability to work efficiently in intra-disciplinary teams by performing experiments as a pair in the lab and ability to work individually by writing reports on these experiments and taking exams.
6 3 B
5) Gains the ability to communicate effectively both orally and in writing by following the text book, lab manual and teaching and writing reports and exams in English.
7 1, 2, 3 A, B
6) Recognizes the need for lifelong learning; ability to access information, to follow developments in science and nanotechnology, and to continue to educate him/herself on these topics.
8 1, 2 A, B
7) Gains knowledge about nanotechnology and the global and societal effects of nanotechnology on health, environment, and safety.
11 1, 2 A, B
Teaching Methods: 1: Lecture, 2: Question-Answer, 3: Lab, 4: Case-study
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Project
COURSE CONTENT
Week Topics Study Materials
1 INTRODUCTIONS, COLLOID AND SURFACE CHEMISTRY Textbook
2 MOLECULAR INTERACTIONS, SELF-ASSEMBLY, BROWNIAN MOTION, SEDIMENTATION
EXPERIMENT: SEDIMENTATION
Textbook & Lab Manual
3 SURFACE CHEMISTRY. SURFACE TENSION, CAPILLARY ACTION, CONTACT ANGLE, METHODS OF SURFACE TENSION MEASUREMENT
Textbook
4 SURFACTANTS, MICELLES, PACKING PARAMETER, CMC, ETC
EXPERIMENT: FACTORS AFFECTING SURFACE TENSION
Textbook & Lab Manual
5 ELECTROSTATICS
EXPERIMENT: ADSORPTION OF POLYELECTROLYTES
Textbook & Lab Manual
6 COLLOIDAL STABILITY
EXPERIMENT: FLOCCULATION AND COAGUATION
Textbook & Lab Manual
7 PHASE DIAGRAMS. VESICLES, MICROEMULSİONS, EMULSIONS, ETC
EXPERIMENT: PREPARATION OF DIFFERENT COLLOIDAL STRUCTURES
Textbook & Lab Manual
8 REVIEW AND MIDTERM 1 Textbook
9 POLYMERS IN SOLUTION
EXPERIMENT: DETERMINATION OF POLYMER SHAPE USING VISCOSITY MEASUREMENTS
Textbook & Lab Manual
10 NANOPARTICLES AND METHODS OF SYNTHESIS
EXPERIMENT: MAGNETITE SYNTHESIS
Textbook & Lab Manual
11 TECHNIQUES USED IN SIZE DETERMINATION
DLS AND DISCUSSION OF TEM RESULTS
Textbook
12 TECHNIQUES USED FOR CRYSTAL STRUCTURE (XRD) AND EVALUATION OF DATA
Textbook
13 POPULAR TOPICS BY STUDENTS Textbook
14 REVIEW AND MIDTERM 2 Textbook
RECOMMENDED SOURCES
Textbook Introduction to Modern Colloid Science, R. Hunter, Oxford Press
Additional Resources Laboratory Experiments Manual
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 2 62
Lab Reports + Lab Performance 7 38
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 35
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 65
Total 100
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level. x
2 Have a wide and deep knowledge in his/her field including the latest progresses. x
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. x
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. x
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
x
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding two midterms: 13x Total course hours) 13 4 52
Hours for off-the-classroom study (Pre-study, practice) 13 7 91
Midterm examination 2 2 4
Reports 7 3 21
Final examination 1 3 3
Total Work Load 171
Total Work Load / 25 (h) 6.84
ECTS Credit of the Course 7
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Advanced Biotechnology ChBE 573 1 3 + 0 3 7
Prerequisites -
Language of Instruction English
Course Level Ph.D. (third cycle program)
Course Type Elective
Course Coordinator
Instructors
Assistants
Goals The aim of this course is to teach the basic concepts of chemical engineering applied for biotechnology
Content
Advanced unit operations, transport phenomena and thermodynamics as applied to biological systems with extensive computer applications and analytical mathematical analysis through selected examples about industrial and metabolic processes
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Learns the Basic Principles of Biotechnology 1 C
2) Acquires knowledge about enzyme techniques and the biocatalysis
1,2 C
3) Acquires knowledge about living organism applied in biotechnology
1,2,3 ,C
4) Gains the ability to design of the Bioreactors and Fermentors
1,2,3 A,C
5) Acquires knowledge about unit operations and transport phenomena in Biotechnology.
1, 9,12 A,C
6) Analyzes Industrial applications of Biotechnology. 1,3 A,C
Teaching Methods:
1: Lecture, 2: Question-Answer, 3: Discussion, 9: Term paper, 12: Case Study
Assessment A: Testing, C: Homework
Methods:
COURSE CONTENT
Week Topics Study Materials
1 Introduction
2 Basic Principles of Biotechnology Text Book
3 Proteins and their synthesis Additional Resources
4 Proteins and enzymes Additional Resources
5 Basics of enzyme kinetics Additional Resources
6 Fundamentals of designing bioreactors Text Book
7 Midterm Exam
8 A little Microbiology Text Book
9 Kinetcis of substrate Utilization and biomass production Text Book
10 Transport Phenomena in Bioprocess Systems Text Book
11 Industrial Applications of Biotechnology Text Book
12 Project respresentation oral
13 General Revision
14 Midterm Exam II
RECOMMENDED SOURCES
Textbook
Bailey, James E., and David F. Ollis. “ Biochemical Engineering Fundamentals. “ New York, NY: McGraw-Hill Education, 1986
Additional Resources
Alan Wiseman, “ Principles of Biotechnology”, Surrey Uni. Press. David L. Nelson, Michael M. Cox, “ Lehninger – Principles of Biochemistry “,W. H. Freeman; 5th ed. Ghasem D. Najafpour, “ Biochemical Engineering and Biotechnology “, Elsevier
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 2 20
Term Paper Project 1 20
Homeworks 1 15
seminar (oral representation) 1 25
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 60
Total 100
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5 1 Understand and apply fundamental sciences, mathematics and engineering
sciences at high level. X
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field. X
5 Understand a genuine research process independently, design, apply and carry through; manage this process. X
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media. X
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization. X
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten. X
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility. X
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam weeks: 14x Total course hours) 14 3 42
Hours for off-the-classroom study (Pre-study, practice) 14 9 126
Midterm examination 2 3 6
Final examination 1 3 3
Total Work Load 177
Total Work Load / 25 (h)
ECTS Credit of the Course 7.08
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
ADVANCED POLYMER CHEMISTRY CHBE 581 1 3 + 0 3 7
Prerequisites -
Language of Instruction English
Course Level Graduate Degree
Course Type Technical Elective
Course Coordinator Assist. Prof. Dr. Erde Can
Instructors Assist. Prof. Dr. Erde Can
Assistants -
Goals
The aim of this course is to provide students with an advanced knowledge of polymer chemistry, polymerization reactions, polymer types, polymer structure - property relationships, polymerization and polymer characterization techniques and polymer applications
Content
Basic principles of polymer chemistry, polymer classifications, the chemical structures of a variety of polymers, polymerization reactions, mechanisms and kinetics, polymer structure - property relationships, polymerization techniques, techniques for molecular and morphological and physical property characterization, applications of polymers. Term project.
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Acquires expanded and in-depth information of the basic principles of polymer chemistry, polymer classifications, the chemical structures of a variety of polymers, polymerization reactions, mechanisms and kinetics, polymer structure - property relationships and ability to use theoretical and applied information in these areas to solve polymer engineering problems
1 1,2 A
2) Acquires expanded knowledge of the various applications of polymers 2 1,12 A,D
3) Acquires expanded knowledge of advanced polymeric materials used in current applications (polymer nano-composites, fire-resistant polymers, liquid crystalline polymers, conductive polymers, biodegradable polymers, biocompatible polymers for
2,3 12 D
medical applications..) and ability to access information and to follow developments in these areas. 4) Learns polymerization techniques, techniques for polymer molecular, morphological and physical property characterization and their respective constraints.
1,2 1,2 A
5) Acquires knowledge about the global and societal effects of polymer engineering practices on health (eg.biomedical applications of polymers) and environment and contemporary issues (eg. plastic wastes, recyclable and biodegradable polymers..)
2,3 1,12 D
6) Gains the ability to work efficiently in intra-disciplinary teams in project assignments and ability to communicate effectively both orally and in writing in English (and ability to communicate stages and results of his/her studies in a systematic and clear manner orally and in writing in intradisciplinary national and international settings) via preparation of project reports and presentations on novel and developing applications of polymeric materials
2,3,8 2,12 D
Teaching Methods:
1: Lecture, 2: Question-Answer, 3: Discussion, 9: Simulation, 12: Case Study
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Project
COURSE CONTENT
Week Topics Study Materials
1 Introduction to Polymer Science (Basic concepts, classification of polymers, natural and synthetic polymers..)
Textbook-Lecture Notes
2 Polymer structure, molecular weight and molecular weight distributions
Textbook-Lecture Notes
3 Step-Reaction Polymerization – Condensation Polymerization (Mechanisms and kinetics)
Textbook-Lecture Notes
4 Addition Polymerization - Radical Chain Polymerization (Mechanisms and kinetics)
Textbook-Lecture Notes
5 Ionic and Coordination Polymerizations (Mechanisms and kinetics) Textbook-Lecture
Notes
6 Copolymerization Textbook-Lecture
Notes
7 MIDTERM EXAM I Textbook-Lecture Notes
8 Polymerization Techniques (Bulk, solution, suspension, emulsion polymerization and polymerization in supercritical fluids)
Textbook-Lecture Notes
9
Polymer structure and physical properties I (Morphology and Order in Crystalline Polymers, Rheology and the Mechanical Properties of Polymers, viscous flow, rubber elasticity, viscoelasticity, glassy state and the glass transition)
Textbook-Lecture Notes
10 Polymer structure and physical properties II (Mechanical properties of crystalline polymers, and the crystalline melting point)
Textbook-Lecture Notes
11 Polymer conformation, solutions and Chain Dimensions Textbook-Lecture
Notes
12 Polymer characterization techniques (Methods for polymer molecular, morphological and physical property characterization)
Textbook-Lecture Notes
13 Industrially Important Polymers and Applications (Commodity thermoplastics, elastomers, thermosets and engineering and specialty polymers)
Textbook-Lecture Notes
14 Project presentataions -
RECOMMENDED SOURCES
Textbook
“Principles of Polymerization”, G. Odian,3rd Edition, John Wiley&Sons Inc, New York, 1991
“Polymer Science and Technology”, J.R. Fried, 2nd Edition, Prentice Hall, NJ, 2008
Additional Resources “Principles of Polymer Engineering”, N.G.McCrum, C.P.Buckley, C.B.Bucknall, 2nd Edition, Oxford University Press, New York
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 1 64
Project 1 36
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 45
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 55
Total 100
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level. X
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten.
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam weeks: 13x Total course hours) 13 3 39
Hours for off-the-classroom study (Pre-study, practice) 14 4 56
Midterm examination 1 (10+2) 12
Project 1 40 40
Final examination 1 (15+3) 18
Total Work Load 165
Total Work Load / 25 (h) 6.6
ECTS Credit of the Course 7
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
SPECIAL TOPICS II in CHBE: Green Engineering and Sustainability
CHBE585 2 3 + 0 3 7
Prerequisites Master's Degree in Chemical Engineering
Language of Instruction
English
Course Level PhD (8th Cycle)
Course Type Elective
Course Coordinator
Instructors Prof Dr Sevil Ünal
Assistants
Goals
The aim of this course is i) to aid postgraduate students in becoming environmentally knowledgeable and skilled and dedicated chemical engineers who are willing to work toward achieving and maintaining a sustainability in their chemical engineering practices, both economically and environmentally ii) to acquaint them with “green engineering” principles and practices; iii)to develop their skills for conducting Life Cycle Assesment (LCA) in chemical engineering processes.
Content
Sustainability and sustainable development; Formation of the Earth, evolution of life; The biosphere, the Earth and its environment; Resources of the Earth and their utilization, pollution; Green engineering and the responsibilities of chemical engineers; Industrial ecology, Life Cycle Assessment (LCA).
Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Understands the uniqueness of the biosphere and the role of the engineer in upsetting the delicate balances required;
2 1,2 A
2) Gains practice of the profession with awareness and respect for the environment;
2,4 1,2,4 A,D
3) Understands the requirements for sustainable development;
2 1,2 A
4) Gains the ability and skill in applying green engineering principles when and where needed;
2,4,5 1,2,4 A,D
5) Gains the ability and skill to conduct LCA and to research/find/adapt the necessary data for the analysis;
2,4,5 1,2,4 A,D
6) Gains the ability for presentation of the term project and communication in English of the methodology and findings.
8,9 1,2,4 D
Teaching Methods: 1: Lecture, 2: Question-Answer, 4: Case-study
Assessment Methods: A: Testing, D: Project
COURSE CONTENT
Week Topics Study Materials
1 Current environmental issiues and sustainability (RS)
2 Sustainable development (RS)
3 Formation of the Earth, evolution of life (RS)
4 The Biosphere and its workings (RS)
5 The Earth, its resources and environment (RS)
6 Pollution (RS)
7 Midterm Exam
8 Green Engineering (RS)
9 Industrial ecology, “zero waste” concept (RS)
10 Introduction to Life Cycle Assesment (LCA) (RS)
11 LCA: case studies/practices Student research
12 LCA: case studies/practices “”
13 LCA Project presentations/discussions “”
14 LCA Project presentations/discussions “”
RECOMMENDED SOURCES (RS)
ENERGY: Principles, problems, alternatives, J. Priest Pollution Prevention: Fundamentals and Practice, Paul L. Bishop, McGraw-Hill International Editions Introduction to Engineering and the Environment, Edward S. Rubin, McGraw-Hill International Editions
Environmental Science, K. Arms, Saunders College Publishing Environment, P.H.Rawen, L.R. Berg, G.B. Johnson, Saunders College Publishing ÇEVRE:Bilinci, Bilgisi ve Eğitimi, S. Ünal, E.Mançuhan ve A.A. Sayar, Marmara Üniversitesi Yayınları
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-terms 1 50
Projects 1 50
Total 100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE 40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE 60
Total 100
COURSE CATEGORY Expertise/Field Courses
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level.
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research.
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field. X
5 Understand a genuine research process independently, design, apply and carry through; manage this process. X
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization.
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten. X
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam days: 13x Total course hours) 13 3 39
Hours for off-the-classroom study (Pre-study, practice) 14 6 84
Midterm examination 1 2 2
LCA (practice) Project / Presentation 1 12 12
LCA term Project / Presentation 1 24 24
Final examination 1 3 3
Total Work Load 164
Total Work Load / 25 (h) 6.6
ECTS Credit of the Course 7
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
SEMINAR CHBE 690 1 0+0 0 2
Prerequisites None
Language of Instruction English
Course Level Ph.D. Degree (Third Cycle Programmes)
Course Type Compulsory
Course Coordinator
Instructors
Assistants
Goals
The aim of this course is, to broaden the student’s mind in recent topics with the seminars given by guest speakers, academicians and graduate students from Chemistry, Chemical Engineering and Bioengineering disciplines.
Content Seminer presentation about the research topics in Chemistry, Chemical Engineering and Bioengineering and learn the presented topics.
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) He/She gathers together the basic information on which the research topic is based on.
2,3 1, 4
2) He/She analyzes the research data and presents them in a report.
7 1,3,4
3) He/She prepares a presentation and gives this presentation in which the gathered information and discussed results are introduced.
8,9,10 1,2,4
4) He/She analyzes the presentation, considers the results from different point of view and asks questions.
7 2
Teaching Methods: 1: Lecture, 2: Question-Answer, 3: Lab, 4: Case-study
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Project
COURSE CONTENT
Week Topics Study Materials
1 SEMINAR
2 SEMINAR
3 SEMINAR
4 SEMINAR
5 SEMINAR
6 SEMINAR
7 SEMINAR
8 SEMINAR
9 SEMINAR
10 SEMINAR
11 SEMINAR
12 SEMINAR
13 SEMINAR
14 SEMINAR
RECOMMENDED SOURCES
Textbook
Additional Resources Academic publications
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
COURSE CATEGORY Expertise Course
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level.
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field.
5 Understand a genuine research process independently, design, apply and carry through; manage this process.
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media.
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization. X
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten. X
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility. X
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam weeks: 14x Total course hours) 14 2 28
Hours for off-the-classroom study (Pre-study, practice) 1 20 20
Total Work Load 48
Total Work Load / 25 (h) 1.92
ECTS Credit of the Course 2
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Qualifying Exam Preparation CHBE 691 NC 30
Prerequisites
Language of Instruction English
Course Level Ph.D.
Course Type Compulsory
Course Coordinator Süheyla Uzman
Instructors
Assistants
Goals This course is designed to prepare the Ph.D. students for the qualifying exam.
Content
In this course, the student carries out an independent study to prepare for the qualifying exam. At the end of the course, the student takes a written and oral qualifying exam to demonstrate that he/she has sufficient knowledge about the fundamental subjects in his/her field and that he/she is capable of conducting scientific reseach towards writing a Ph.D. thesis.
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
Possess adequte knowledge of fundamental subjects within the field of study
1,2 1 A
Ability to conduct research in the area of concentration
3,4,5 1 A
Ability to contribute to the existing scientific knowledge in the area of concentration
4,6,7 1 A
Ability to communicate technical content in writing and orally 6,8,9
1 A
Teaching Methods: 1: Independent study
Assessment Methods: A: Qualifying Exam (written and oral)
COURSE CONTENT
Week Topics Study Materials
1-14 Independent study in preparation for the qualifying exam
Variety of textbooks in the field of Chemical
Engineering, Books and
articles related to the thesis topic.
RECOMMENDED SOURCES
Textbook
Additional Resources
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Qualifying exam (written) 1 50
Qualifying exam (oral) 1 50
Total 100
Contribution of Final Examination to Overall Grade 100
Contribution of In-Term Studies to Overall Grade 0
Total 100
COURSE CATEGORY Expertise
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply natural sciences, mathematics and engineering sciences in advanced level. X
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research.
X
4 Ability to do an extensive study which brings in novelty to science and technology, develop a new scientific method or technological product/process, or apply a know method to a new field.
X
5 Understand a genuine research process independently, design, apply and carry through; manage the process X
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media. X
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization. X
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio C1 orally and written.
X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and written. X
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility.
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Independent study 1 750 750
Qualifying exam (written) 1 4 6
Qualifying exam (oral) 1 2 2
Total Work Load 752
Total Work Load / 25(h) 30.32
ECTS Credit of the Course 30
COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
PhD Thesis ChBE 700 5,6,7,8
30
Prerequisites Compulsory and Elective Courses, Proficiency Examination
Language of Instruction English
Course Level Doctorate (Third Cycle Programme)
Course Type Compulsory
Course Coordinator
Instructors Chem. Eng. Dept. Faculty
Assistants
Goals The aim of this course is the preparation and Defense of an original Thesis in the field of Chemical Engineering
Content Fundamental and advanced principles of Chemical Engineering, Applications and theses
Course Learning Outcomes Program Learning
Outcomes
Teaching Methods
Assessment Methods
1) Gains ability to work on an original scientific Thesis.
2,3,4,5 4,5 D
2) Acquires extensive and original knowledge about the thesis topic
6,7,8, 4,5 D
3)Gains ability to complete an original scientific Thesis. Ability to defend the thesis
6,7,8,9 4,5 D
4) Gains ability to publish scientific results 6,8,9,10 5 D
Teaching Methods: 1: Lecture, 2: Question-Answer, 3: Lab, 4: Case-study 5.Discussion
Assessment Methods: A: Testing, B: Experiment, C: Homework, D: Thesis Defense
COURSE CONTENT
Week Topics Study Materials
1 Thesis Relevant scientific Publications
2 Thesis Relevant scientific Publications
3 Thesis Relevant scientific Publications
4 Thesis Relevant scientific Publications
5 Thesis Relevant scientific Publications
6 Thesis Relevant scientific Publications
7 Thesis Relevant scientific Publications
8 Thesis Relevant scientific Publications
9 Thesis Relevant scientific Publications
10 Thesis Relevant scientific Publications
11 Thesis Relevant scientific Publications
12 Thesis Relevant scientific Publications
13 Thesis Relevant scientific Publications
14 Thesis Relevant scientific Publications
RECOMMENDED SOURCES
Textbook Relevant scientific Publications
Additional Resources
MATERIAL SHARING
Documents
Assignments
Exams
ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Thesis Defence 100
Total 100
COURSE CATEGORY Expertise/
COURSE'S CONTRIBUTION TO PROGRAM
No Program Learning Outcomes Contribution
1 2 3 4 5
1 Understand and apply fundamental sciences, mathematics and engineering sciences at high level.
2 Have a wide and deep knowledge in his/her field including the latest progresses. X
3 Reach the latest knowledge in the field and through its comprehension possess high level competence in required methods and skills for doing research. X
4 Ability to do an extensive study which brings novelty to science and technology, develop a new scientific method or technological product/process, or apply a known method to a new field. X
5 Understand a genuine research process independently, design, apply and carry through; manage this process. X
6 Contribute to science and technology literature by publishing the outcomes of his/her academic studies in prestigious media. X
7 Able to do critical analysis, synthesis and evaluation of ideas and progresses in his/her specialization. X
8 Able to communicate and discuss at high level orally, written and visually by using a language at least at the level of European Language Portfolio B2 orally and written. X
9 Able to communicate with persons in his/her career and widely with scientific and social ensemble orally and writtten. X
10 Able to evaluate scientific, technological, social and cultural developments and transfer them to society with senses of scientific disinterest and ethical responsibility. X
ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration (Hour)
Total Workload
(Hour)
Course Duration (Excluding the exam weeks: 14x Total course hours) 14 40 560
Hours for off-the-classroom study (Pre-study, practice) 14 12 168
Total Work Load 728
Total Work Load / 25 (h) 29,12
ECTS Credit of the Course 30
Program Learning Outcomes vs. Courses Course PLO1 PLO2 PLO3 PLO4 PLO5 PLO6 PLO7 PLO8 PLO9 PLO10
CHBE 512 Modeling and Analysis of Chemical Engineering Systems
5 0 0 0 0 0 0 3 0 0
CHBE 514 Advanced Engineering Thermodynamics
4 4 4 0 0 0 0 4 0 0
CHBE 534 Transport Phenomena 4 4 4 0 0 0 0 4 0 0
CHBE 562 Advanced Chemical and Biological Engineering
5 5 5 5 5 3 5 0 3 3
CHBE 565 Fundamentals of Colloid and Surface Chemistry
2 5 3 0 0 0 0 5 0 1
CHBE 573 Advanced Biotechnology 5 4 4 5 4 5 4 3 4 3
CHBE 581 Advanced Polymer Chemistry 5 5 5 0 0 0 0 5 0 0
CHBE 585 Special Topics II in CHBE: Green Engineering and Sustainability
0 5 0 5 4 0 0 5 4 0
CHBE 690 Seminar 0 5 5 0 0 0 5 5 5 4
CHBE 700 Ph.D. Thesis 0 5 5 5 5 5 5 5 5 5
Course Category List ECTS
Field Courses CHBE 512 Modeling and Analysis of Chemical Engineering Systems 10 CHBE 514 Advanced Engineering Thermodynamics 10 CHBE 534 Transport Phenomena 10 CHBE 562 Advanced Chemical and Biological Reaction Engineering 7 CHBE 690 Seminar 2 CHBE 692 Qualifying Exam Preparation 30 Total 70
Expertise Courses CHBE 525 Advanced Instrumental Anlaysis 7 CHBE 581 Advanced Polymer Chemistry 7 CHBE 585 Special Topics II in CHBE: Green Engineering and Sustainability 7
Total 21
CHBE 700 Ph.D. Thesis (4 semesters) 120
Total ECTS of all courses 211
Level of Qualification: This Graduate Programme is subjected to third cycle program with 211 ECTS credits for the doctorate degree in the field of Chemical Engineering. Students who complete the program successfully with all the program requirements receive a doctorate (Ph.D.) degree in Chemical Engineering Admission Requirements:
To apply for a doctorate program, an Master’s degree must be held or expected to be held by the end of the term of application and the requirements given below must be met.
- A minimum score of 55 from ALES or 149 from GRE (Quantitative Reasoning).
- A minimum of 55 from YDS or 66 from TOEFL IBT. Canditates who don’t have aforementioned scores are required to be successful in the Yeditepe University’s proficiency exam.
- Candidates are required to be successful in the interview held by the department they are applying for.
Or the students who have the BSc degree whofullfil the following requirements may apply for the degree:
- A minimum B.Sc. cumulative grade point average (CGPA) of 3.00 out of 4.00.
- A minimum score of 80 from ALES or 156 from GRE (Quantitative Reasoning).
- A minimum of 55 from YDS or 66 from TOEFL IBT. Canditates who don’t have aforementioned scores are required to be successful in the Yeditepe University’s proficiency exam.
- Candidates are required to be successful in the interview held by the department they are applying for.
Employment Opportunities and Promotion Our graduates may be in research activities in many national or international research instititues and universities as well as working in many national and international companies in chemical industry as engineers and managing directors. Graduation Requirements To earn Doctorate degree in Chemical Engineering, students who have a B.S. degree must complete 4 compulsory, 10 elective courses and a non-credit seminar course (42 credits, 259 ECTS) with a minimum CGPA of 3.0 (out of 4.0), be successful in the
Qualifying Examination, must prepare a Ph.D. Thesis and be succesful in the Dissertation Defense. To earn Doctorate degree in Chemical Engineering, students who have a M.Sc. degree must complete 5 compulsory and 3 elective courses and a non-credit seminar course (21 credits, 211 ECTS), be successful in the Qualifying Examination, must prepare a Ph.D. Thesis and be succesful in the Dissertation Defense.
Contact Details:
Head of Chemical Engineering Department:
Assoc. Prof. Tuğba Davran Candan : E-mail: tugba.candan@yeditepe.edu.tr Tel: 2754 ECTS Coordinators
Assist. Prof. Semin Funda Oğuz: E-mail: funda.oguz@yeditepe.edu.tr
Tel: 1474
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